weingart



COMPENSATING SYSTEM FOR CONDITION RESPONSIVE MEASURING INSTRUMENTS June 26, 1945. R. 1. N. WEINGART Filed April 21, 1945 Ow r m u INVENTOR. $5641 14 Patented June 26, 1945 COMPENSATING SYSTEM FOR CONDITION RESPONSIVE MEASURING INSTRUMENTS v Richard I. N. Weingart, Glen Head, N. Y. Application April 21, 1945,,Serial No. 483,858

13 Claims. (01; 13-310) This invention relates to an improved compensating or differential struments, both indicating and recording, and

has for its principal object the provision of an improved apparatus and method for correcting the reading in measuring instruments, for changes in barometric pressure; ambient or instrument casing temperatures, and the like. other words, the present invention is directed to an improved means of impressing upon one indicator the sum or difference of the movement of two condition-responsive elements.

Measuring instruments, such as pressure gauges, altimeters, thermometers, and the like, are initially calibrated under certain conditions system for measuring inof temperature and atmospheric pressure, and in their subsequent use they are accurate only if used under those identical conditions. For most purposes, a high order of accuracy is not required, but in cases wherein it is, some compensating system must be employed unless individual corrections are made at each reading, which is time-consuming and quite impossible in the case of recording instruments.

Any thermometer system, for instance, emcapillary tube is subject to the temperature which is being measured in the sensitive which the cap'llary tubing and case are subjected. If the ratio between the bulb volume and the tube volume is large enough, the error can be reduced to a certain extent, but this is seldom practical. Where the greatest accuracy is required, however, the usual method of compensating for the error is to'employ a secondary actuating mechanism of identical size and filling, coupled in opposition to the primary acpressed upon tory mean is reached.

sive element into rotary motion in the pointer shaft or pen arm. There also is a direct linkage connection between the secondary responsive element andthis primary translating movement.

.,This arrangement necessitates a relatively large number of I pivots between the tworesponsive eleinent s"and the eventual pointer shaft with the usual, number of lin bell crank or other levers, or the like. The maintenance cost of instruments of this characteris high since bearings and shafts wear down, and, the instrument soon becomes inaccurate, due to'fithe friction in the increased linkage.

Instruments of this characterware also diflicult to calibrate since the two responsive elements must be separately calibrated to cause the individual changes in conditions to be properly imthe pointer shaft or pen'arm. A change of calibration in one element affects-the existing calibration of the other, thus necessitate. ing back-and-forth calibration until a'satisfac- In the present invention,

, the calibration of each of the respective elements,

in its effect on the pointer, maybe made separately, and the change in calibration, in one element in no way affects the response of the pointer to the other. It isa particular object of the present invention to provide an improved compensating system and apparatus which will avoid all of the aforemen 'oned difficulties, and will provide a more accurate and fully compensated measuring instrument at lesser initial cost, and which has a far less cost of upkeep.

A measuring instrument employing a compensating system of the present invention util- 1 1285 a movement wherein the driven element is a tuating mechanism. The second tube is run parallel to the bulb capillary so the errors that develop along the tubing are compensated for. In the event that only the temperature in the instrument casing is to be compensated for, some simple temperature-responsive element, such as a bi-metallic strip, is used as a part of the linkage to the pointer shaft or pen arm.

So far as is known, in every instance in the prior art wherein a fully compensated system has I been provided for, the secondary responsive mechanism is connected to, and works directly in opposition to, or in conjunction with, the primary condition-responsive means. 'In other words, in pressure gauges, for instance, those employing a Bourdon tube or a metallic bellows. there is a movement for translating the substantially longitudinal motion of the primary respongenerally cylindrical member having an external helical fin or thread, or a helical recess, and wherein the driving element is a member which works against the thread, usually in a cam-like manner, and may comprise a single-surfaced driving cam or single-toothed gear having a driving surface disposed generally to the lead angle or the helical fin, the driving cam being mounted on a shaft generally parallel with the axis of the driven element. The driving element, on the other hand, may include a member moving generally parallel with the axis of the driven member, and include a portion which contacts the spiral thread. Otherforms of driving elements for this type of helical driven member may also be used.

I In accordance with the present invention, the primary condition-responsive means are conto the driving element of the nected directly 'an automatic compensating system formeasuring instruments. A still further object of the invention is to provide a. novel mechanical movement wherein two separate driving members, each acting independently of the other, may act upon a driven shaft. Another object of. the invention is the provision of a unique mechanical movement comprising a helical member associated with a shaft which is Journalled for rotative and longitudinal movement. One element, which may be a driving element, comprises a member which act upon the helical surface. The shaft may be moved, also, longitudinally of its axis by means of another element acting upon it. The movement of either of these driving elements separately produces clockwise or counter-clockwise rotation in the shaft, depending upon the direction in which it moves. When both driving members act simultaneously, the resultant movement of the shaft is proportionate to the sum or difference of these applied movements.

In the drawing:

Fig. 1 is a perspective view, partly in section. of one compensating system embodying the present invention.

Fig. 2 is a perspective view, partly in section, of another compensating system of the present invention.

Fig. 3 shows an alternative form of thrustas'rasss area which is to be measured. Tube 2! is rigidly mounted on the bellows, and such tube, in turn, is mounted on a bracket II comprising a portion of the frame member. A fixed arm II is carried on the upper surface of the bellows, and such arm is connected by means of a link 32 with one terminal of driving lever 2|. This terminal of the driving lever may have a plurality of apertures 34 therein to permit calibration of the driving member.

The auxiliary or compensating system comprises, in this instance, a diaphragm unit 31 having a diaphragm II on its upper surface which is responsive to changes in barometric pressure. The diaphragm unit 31 may be rigidly mounted by means of support 39 on frame member 44. A post 4| is rigidly secured on the upper surface of the diaphragm, such post being connected by means of link 42 with one terminal of driving arm 43. This arm is mounted on a shaft 44 pivotally supported in frame elements 45. At

one end, the arm likewise has a plurality of bearing element for the end 'ofthe driven shaft.

Fig. 4 shows the use of a bi-metallic element.

Fig. 5 is a side elevation of a slightly modified form of the present invention wherein thehelical element is keyed. to the shaft for longitudinal, though not rotative, movement relative to such shaft. the. secondary driving element producing longitudinal movement of the helical element and not to the shaft.

The drawings are quite schematic in character and are not intended as working drawings. The operative parts of the system shown in Fig. 1 may also be positioned within a suitable housing (not shown), the moving parts being Journalled in frame members which are shown in a fragmentary manner. Thus, the driven element consists of a shaft formedin two axially aligned sections l0 and II, and having a helical or spiral element l2 therebetween. The spiral element. in this instance, is illustrated as being formed from an elongated strip of flat sheet metal twisted in the manner shown. Shaft section III is journalled in bearing element ll supported on frame member l4. Shaft section II is iournalled in a frame member II and carries a .conventional pointer II at its outer end. A hair spring II is adapted to keep the gear parts tight and prevent backlash. a

The driving member consists of a centrallypivoted lever or driving arm 2| having a bifurcated or forked end portion 22 which receives the spiral between the arms of such forked portion. The lever is mounted on shaft 24, which is joumalled in spaced frame members 25 at right angles to the axis of the driven shaft Il I. In this instance, the primary condition-responsive element is a vacuum bellows 28 29 at the lower end which passes having a tube to the vacuum apertures 46 to permit calibration, and at its other end the arm has an elongated slot 49 which receives a pin 50 associated with a bifurcated member II which is carried at the lower end of a thrust-bearing element I2. The upper end of this thrust-bearing member contacts the lower end of shaft l0. Accordingly, it will be seen that as the vacuum to be measured increases, bellows element 2! contracts, thereby causing arm 3| and link 32 to move downwardly, thereby elevating the opposite end of driving arm 2|. This causes shaft H to rotate in a clockwise direction.

Downward movement of the upper or free end of bellows unit 28 is caused by an increase in the vacuum in tube 29. Strictly speaking, however,

downward movement of the bellows unit is brought about by atmospheric pressure acting externally. Accordingly, the movement increases or decreases for any given degree of vacuum, according to the changes of atmospheric pressure. It will be apparent, then, that the reading of pointer I7 is accurate only when the instrument is used under barometric pressures which are the same as when the instrument was calibrated. In the present system, however, the barometric pressure also acts upon diaphragm 38, and as this pressure increases, the diaphragm is depressed, thereby causing post 4| and arm 42 to move the right-hand end of driving arm 43 downwardly, thus raising the opposite end and causing thrust bearing 52 to move upwardly, thus also raising driven shaft [0. This imparts counter-clockwise rotation to shaft Ii and pointer I! as a result of the screw action between helical element l2 and the forked driver 22.

If, on the other hand, there is a decrease in barometric pressure, the reverse action takes place, thereby, in either instance, compensating for the error of indication of vacuum by the pointer for any given degree of vacuum, which error might be caused by a varation of barometric pressure from that under which the instrument was calibrated. Thus, the final result indicated by the pointer is the result of the movement of bellows 28, resulting from the atmospheric pressure, minus the degree of such increased movesubstance which expands and contracts with changes in temperature, and comprising the usual Bourdon tube 60 mounted in a block 6| which is provided with a connection 62 to which is secured a conventional capillary tube designated in broken lines at 63, which leads to a thermometer bulb 64 which is positioned inside a boiler or other structure, the temperature of which is to be measured. As the temperature in the structure increases, the pressure in the capillary tube and in the Bourdon tube increases, thus imparting movement to the outer terminal I55 of the Bourdon tube. A link 66 connects this outer end to one end of a driving arm 61 which is carried on a shaft 68 pivotally mounted at 69 in suitable frame elements. A plurality of apertures 10 in this terminal of the arm 61 primary thermometer The driving member system. comprises a generally sector-shaped cam element 1| mounted at the opposite end of arm 61, the driving surface of which engages a generally helical thread 12 formed on the exterior surface of a substantially cylindrical driven element 13 mounted on shaft 14. This driving surface of cam element 1| is disposed generally to the lead angle of the helical thread. The upper end of shaft 14 is journalled at 15 in a frame member and also carries a pointer 16. Rotation of the driven member in one direction is caused by movement of the cam 1| against the external fin or thread 12, and rotation in the opposite direction is caused by means of a hair spring 18, as opposite movement of cam 1| permits opposite rotation of the thread element 12.

The ambient temperature-compensating system comprises a second capillary tube 80 which is connected at 8| to a bellows unit 82, tube 8| being rigidly secured to a bracket 83 comprising a portion of the frame element. Tube 80, as it leaves the instrument casing, closely follows tube 63 to its end and stops just short of, and outside, the boiler or other unit, the temperature of which is being measured. The outer terminal of tube 80 is indicated at 86. The length of tubes 63 and 80 may, in some instances, be several hundred feet, and in accordance with usual practice, the two tubes are covered as by some coveringelement 81. jected to the same temperature variations as is tube 63, except that auxiliary tube 80 stops short of the boiler.

The operation of this system is as follows: Temperature in the boiler acting on the contents of bulb 66, plus the temperature surrounding capillary tube 63 acting on the contents thereof, plus the temperature acting on the contents of Bourdon tube 60, causes expansion of the entire confined substance, producing movement at the free end of the Bourdon tube. By virtue of the linkage arrangement between such free end 65 and the driving arm 61, such movement of the Bourdon tube is imparted to the driving face of driving cam 1|, thus permitting clockwise rotation. of shaft 14 due to the action of hair spring 18. When the temperatures decrease, counterclockwise rotation of the driven shaft results. The reading of the pointer at this point would indicate not only the expansion or contraction due to changes of temperature affecting bulb 64, but also any expansion or contraction caused by changes of temperatures surrounding the capillary tube 63 and the Bourdon tube 60. It is, however, desired only to indicate the expansion or permit calibration of the.

driving surface of Secondary capillary tube 80 is sub-- contraction due to the temperature surrounding bulb 64.

Accordingly, the influence of changes in the ambient temperature surrounding the capillary tube 63 and Bourdon tube 60 should be subtracted from, or added to, this reading, as the case may be, by the secondary system comprising capillary tube and bellows 82, which are subjected to the same temperatures as are the capillary tube 63 and Bourdon tube 80. Thus,-as the ambient temperatures increase,'the bellows B2 expands, thereby causing the links 89 and 90 to move downwardly, thereby raising the upper end of driving arm 9|, acting on thrust-bearing pin 91. This moyes Shaft section 14 upwardly, imparting countor-clockwise rotation to this shaft as a result of the screw action between driving cam 1| and external thread 13. This, when properly calibrated, subtracts that movement of the pointer caused by any increase of temperature surrounding capillary tubing '63 and Bourdon tube 60.

When there is a decrease in ambient temperatures, the reverse action takes place. It will be apparent that the calibrating of the primary responsive system is in no way affected or disturbed by the calibration of secondary system, or vice versa, as was earlierrppinted out. This calibration may be effected .while'keeping the temperature of the bulb $4 constant; and changing the ambient temperatures of tubes'03 and 80 and the temperature surrounding Bourdon tube 60 and bellows 82, all as will be appreciated by those skilled in the art.

In the arrangement shown in Fig. 3, a bellows unit I02 is mounted on a frame element I03. A link I04 is pivotally connected at I05 to the bottom of the bellows. Link I04 is connected with an extensible portion I06 of driving arm I01, which latter is centrally pivoted at I08. At its opposite end, driving arm I01 is slotted, as shown at I00, and receives a pin IIO passing through a thrust-bearing eleme'nt III which acts against the lower end of shaft II2, which is journalled at H3 in the'frame element. Shaft ||2 carries the driven helical element II4. This view shows merely an alternative linkage arrangement for connecting the secondary responsive element with the thrust-bearing element acting against one end of the driven shaft. In Fig. 4, a bi-metallic element I20 is mounted at I2| rigidly in the frame. The free end of the bi-metallic element engages a thrust-bearing pin I22 which engages the lower end of driven shaft I23, which is journalled in bearing member'IM.

It will be apparent that the system of the present invention may also be used to show the differential in movement of two separate elements responsive to changes in conditions, one of which is connected to the primary driving element 61, and the other of which is connected to the secondary driving element 9|. When the movement of these elements is equal, and the movements are arranged in opposition to each other, the movement of the one will have a clockwise rotating effect on the pointer, and the movement of the other will have an equal counter-clockwise rotating effect on the pointer, thereby causing the pointer to remain stationary. Should the movement of the primary element be. greater than that of the secondary element, such excess will be indicated by clockwise rotation of the pointer shaft. Should the reverse be true, counter-clockwise rotation would indicate such difference. Such a system will be particularly useful in maintaining equal pressure in two boilers, or in maintaining equal temperatures in two chemical manufacturing processes, and in many other instances wherein duplex gauges or the like are sometimes used. The use of the present system is also much more effective where it is desirable .to indicate the sum of two movements, in which case the two elements are arranged to operate the pointer in the same direction.

The movement of the present invention may have a variety of uses other than in compensated measuring systems or in measuring instruments generally, all as will be appreciated by those skilled in the art. Also, the structures shown and described may be modified considerably without departing from the spirit of the invention. For instance, the secondary movement which produces rotation by moving the shaft longitudinally need not necessarily contact the end of the shaft. If desired, the shaft may have a fixed collar with an annular, peripheral recess which receives a forked driver which may move the shaft in either direction.

Also, it will be apparent that the second driving element need not work directly upon the shaft as by the thrust-bearing element 5 2 of Fig. 1 or 91 of Fig. 2, or against the. fixed collar Just mentioned. For instance, the helical element, in-

dition-responsive means into rotary movement of the indicating shaft comprising a helical driven member associated with the shaft, and a driving member contacting the helical member and exerting a thrust against the same to impart rotation thereto, means connecting the first condition-responsive means with the driving member, means fortranslating the motion of the second condition-responsive means into rotary movement of the pointer shaft, independent of the motion of the first condition-responsive means, said translating means comprising a movable thrust-bearing element contacting the shaft, and means connecting the second condition-responsive means with said thrust-bearing element.

3. In a combined measuring instrument and compensating system therefor, the combination of primary means responsive to changes in a condition such as temperature, pressure, or the like, and a secondary means responsive to changes in an auxiliary condition, such as ambient temperature, temperature of instrument stead of being rigidly mounted on, or formed integrally with, the driven shaft, may be arranged in the manner shown in Fig. 5 wherein cylindrical member I21 formed with helical element I28 may be mounted on shaft I29 and be movable longitudinally thereof. A key element or spline I30 interlocks the cylindrical member I21 and shaft I28, so that there can be relative longitudinal movement therebetween but not relative rotative movement. Sector-shaped cam element Iii is the primary driving element, and pin I82 may be the secondary driving element, such pin contacting the end of cylindrical member I21. Shaft I29 may beiournalled in frame members I", and the usual hair spring I may be employed for driving the shaft in one direction. When this secondary driving element I32 moves against the end of element I 21, such element is rotated without, however, producing longitudinal movement in shaft I23.

What I claim is:

1. In a combined measuring instrument and compensating system therefor, the combination of primary means responsive to changes in a condition, and a secondary means responsive to changes in an auxiliary condition, indicating means including a. shaft, a movement for translating motion of the primary responsive means.-

into rotary movement of the indicating shaft comprising a helical driven member associated with the shaft, and a driving member contacting the helical member and exerting a thrust against the same to impart rotation thereto, means connecting the primary condition-responsive means with the driving member, a movable thrust-bearing element contacting the shaft, and means connecting the secondary condition-responsive means to said movable thrust bearing for producing longitudinal movement of the shaft, thus imparting rotation thereto independent of the rotatlon imparted by movement of the primary driving member.

2. In a measuring instrument of the character described, the combination of a first means responsive to changes in a condition, and a secand means responsive to changes in an auxiliary condition, indicating movement for translating motion of the flrstconmeans including a shaft, a

casing, atmospheric pressure, or the like, a pointer shaft and a pointer carried thereby, a movement for translating motion of the primary condition-responsive means into rotary movement of the pointer shaft comprising a helical driven member associated with the pointer shaft,

' anda driving member contacting the helical the same to impart member and exerting a, thrust against the same to impart rotation thereto, means connecting the primary condition-responsive means with the driving member, a movable thrust-bearing element contacting the pointer shaft to move the same longitudinally, and means for translating movement of the secondary condition-responsive means into longitudinal movement of the pointer shaft, thus imparting rotation thereto independ- 'ent of the rotation imparted .by the primary driving member, said means comprising a connecting element between the secondary condition-responsive means and the thrust-bearing element.

4. In a measuring instrument having means responsive to changes in a, condition, indicating means comprising a pointer shaft and a pointer carried thereby, a movement for translating motion of the conditio -'responsive means into rotary movement of the pointer shaft comprising a helical driven member associated with the pointer shaft, and a primary driving member contacting the helical member and exerting a thrust against rotation thereto, and means connecting the condition-responsive means with the driving member, the combination of a compensating system for the measuring instrument comprising a secondary means responsive to changes in an auxiliary condition, a movable thrust-bearing element contacting the pointer shaft, and means for translating movement of the secondary condition-responsive means into longitudinal movement of the pointer shaft, thus imparting rotation thereto independent of the rotation imparted by the primary driving member, said means comprising a connecting element between the secondary condition-responsive means and the thrust-bearing element.

5. In a measuring instrument provided with a compensating system, the combination of a frame, primary means responsive to changes in a condition, such as temperature, pressure, altitude, or the like, mounted in the frame, and a secondary means responsive to changes in an auxiliary condition such as ambient temperature, temperature of instrument casing, atmospheric pressure, or the like, condition-indicating means the pointer shaft, thus imparting rotation thereincluding a shaft journalled in the frame having to independent of the rotation imparted by the a pointer or a pen arm carried by the shaft, a primary driving member, said means comprising movement for translating motion of the primary a connecting element between the secondary concondition-responsive means into rotary move- 5 dition-responsive means and the thrust-bearing ment of the shaft comprising a helical driven element.

member mounted on the shaft, and a primary In a movement r a measuring in tr ment driving member comprising a generally sectorh vin a p r li y f ns responsive t shaped driving cam contacting the helical memchanges in conditions, the combination of a her and exerting a thrust against the same to 1m. pointer shaft, a helical driven member associated part rotation thereto, means connecting the priwith the shaft, and a driving member contacting mary condition-responsive means with the drivthe helical member and exerting a thrust against ing member, a movable thrust-bearing element. the same to impart rotation thereto, means concontacting the shaft, and means fo trans atin necting one of such condition-responsive means movement of the secondary condition-responsive h the driving r, a movable hr -b rmeans into longitudinal movement of the shaft, i e eme t contacting the shaft, a mea s c thus imparting rotation thereto independent of necting a second responsive m s t e the rotation imparted by the primary driving aring elementfor imp r longitudimember, said means comprising a connectin ele- 'nal movement to the shaft and causing, rotation ment between the secondary ondition-r onas a result of the screw action between the first sive means and the thrustebearing element. driving means and the helical member- 6. In a compensated thermometer system, the 7 9. In a movement for measuring instruments combination of primary means responsive to temhaving a plurality of means responsive to changes -perature changes, a thermometer .bulb positioned in itions, the combination of a p in r sh n the zone to be measured and secondary means a helical driven member associated with the shaft responsive to changes in ambient temperature, a and'being mo e longitudinally t re f, e n capillary tube connecting the bulb with the pricomprisin a y element for interlocking e mary temperature-responsive means, and, a eehelical member and the shaft so asto permit ond capillary tube positioned adjacent t th fir t longitudinal movement therebetween but not reltube but terminating short of said zone, said secative rotative movement, a vi member con- 0nd tube being, connected with the secondary tacting the helical member and exerting a thrust temperature-responsive means, a pointer shaft against the same to impart rotation thereto. and a pointer carried thereby, a movement for ans connecting n f s ht sp translating motion of the primary temperatures me ns w e driving m movable responsive means into ro'tary movement of the thrust-producing element contacting one end of pointer shaft comprising a helical driven member the helical driven member and means connectassociated with the pointer haft and a primary ing a second responsive means with the thrustdriving member contacting the helical member Producing element for imparting bngitudinal and exerting thrust against the same to impart movement to such helical element and causing one-way rotation thereto, and spring means for 40 1"Otittion thereth result of the Screw action imparting opposite rotation to the shaft, means between the first driving means and the helical connecting the primary temperature-responsive member- 1 a means with th driving member, a movable 10. Inamovement for a measuring instrument thrust-bearing element contacting one end of the having means responsive to changes in a condipointer shaft, and means for translating move- 5 tion. e combination of a f a e a driven haft, ment of the secondary temperature-responsive journal means in the frame comprising hes-Tings means into longitudinal movement of the pointer which Permit rota y movement of the shaft as shaft, thus imparting rotation thereto against Well as longitudinal movement thereof relative to the action of the spring means, independent of its axis, a helical member associated with the th r t t imparted by t primary driving shaft, an element contacting the helical memmember, said means comprising a link connecbe! on the pitch helix thereof, a movable thrusttion between the secondary temperature-responbearing el ment contacting one end of the shaft, sive means and the thrust-bearing element. means connecting the o p n iv 7. In a combined measuring instrument and means with the thrust-bearing l t p ocompensating system therefor, the combination ducingi when such thrust-beefing e t s of primary and a secondary/means responsive moved by the condition-responsive means, rotato changes i iti pointer shaft, d tion of the shaft as a result of the screw action pointer carried thereby m t for t between the helical member and the element conlating motion of the primary condition-respon tasting such helical member on its pit h helix.

sive means into rotary movement of the pointer 0 In a movement for a measuring instrument shaft comprising a helical driven member carried ving means re p ve to changes in a condiby the pointer shaft. and a primary driving memtion, the combination of a frame. a driven s ber formed with a driving face disposed general- Jwmai means in the me comprising bearin 1y to the lead angle of the helical member and which permit rotary movement of the shaft as contacting Such M11031 member, exerting a well as longitudinal movement thereof relative to thrust against the same to impart rotation thereits axis, a helical m r associated with the to in one direction, a spring for rotating the shaft Shaft, an element contacting e he ical memin theopposite direction as such opposite rota- 011 the pitch e ix t ereof, a movable thrusttion i permitted by opposite movement of t producing element arranged to move the shaft driving member, means connecting the primary 7 and the helical member longitudinally of their condition-responsive means with the driving axes, and m ns nn tin the condition-remember, a movable thrust-bearing element consponsive means with the movable thrust-protacting the pointer shaft, and means for transducing element, thus causing, when such thrustlating movement of the secondary condition-reproducing element is moved by the condition-responsive means into longitudinal movement of 7s sponsive means, rotation of the shaft as a result of the screw action between the helical member and the element contacting such helical member on its pitch helix.

12. In a movement for a measuring instrument having means responsive to changes in a condition, the combination of a frame, a driven shaft, a helical member associated with the shaft and being movable longitudinally thereof, means comprising a key element for interlocking the helical member and the shaft so as to permit longitudinal movement therebetween but not relative r0- tative movement, an element contacting the helical member on the pitch helix thereof, a, movable thrust-producing element contacting one end of the helical member, and means connecting the condition-responsive means with such thrust-producing element, thus causing, when such thrustproducing element is moved by the condition-responsive means, rotation of the shaft as a result of the screw action between the helical member and the element contacting such helical member on its pitch helix.

13. In a measuring instrument of the character described, the combination of a first means responsive to changes in a condition, and a second means responsive to changes in an auxiliary condition, indicating means including a shaft,

Journal means for the shait permitting rotative movement of such shaft as well as movement thereof longitudinally of its axis a movement for translating motion of the first condition respcnsive means into rotary movement of the indicating shaft comprising a helical driven member associated with the shaft, and a driving member contacting the helical member and exerting a thrust against the same to impart rotation thereto, means connecting the first condition-responsive means with the driving member, means for translating the motion of the second conditionresponsive means into rotary movement of the pointer shaft, independent of the motion 01 the first condition-responsive means, said translating means comprising a movable thrust-producing element arranged to move the shaft and the helical member longitudinally of their axes, means connecting the second condition-responsive means with the thrust-producing. element, thus causing, when such thrust-producing element is moved by the second condition-responsive means, rotation of the shaft as a result of the screw action between the helical member and the driving member contacting such helical member.

RICHARD I. N. WEINGART. 

